JP2022031875A - Electronic clock, time correction method and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an electronic clock which makes operation during time correction to be performed simply.

SOLUTION: An electronic clock of the present invention includes: counting means for counting time (timer circuit 20); inputting means for receiving an input (key switch S1); measuring means for measuring the time during the input is received by the inputting means (control part 70); control means for determining whether or not to change the time difference data set in an own device (control part 70) based on a measurement result of the measuring means; and time correction means for correcting the time counted by the counting means based on the time difference data (control part 70).

SELECTED DRAWING: Figure 2

COPYRIGHT: (C)2022,JPO&INPIT

Description

The present invention relates to an electronic clock, a time adjustment method and a program.

Electronic clocks (clocks, cameras, etc.) that correct the time measured by an internal clock (timekeeping means) based on received radio waves (GPS signals, etc.) are known.

For example, in Patent Document 1, when the power switch is operated in the ON state, the time value of the internal clock is compared with the date and time information in the non-volatile memory, and the former time value is the latest value. Discloses an electronic clock (camera) that writes its timekeeping value to a non-volatile memory and shifts to automatic date / time correction processing using received radio waves when the latter date / time information is the latest value.

According to such an electronic clock, even if the time measured by the internal clock is initialized by replacing the battery, the time measured by the internal clock is automatically corrected based on the received radio wave when the power is turned on thereafter. can do.

Japanese Unexamined Patent Publication No. 2001-228272

By the way, various time adjustment modes for adjusting the time measured by the internal clock can be considered.
For example, as an example, the first time adjustment mode that corrects the time measured by the internal clock based on the received radio wave without changing the time difference data set in the electronic clock, or the electronic device based on the received radio wave. A second time adjustment mode or the like in which the time difference data set in the clock is changed and the time measured by the internal clock is adjusted can be considered.

The time difference data set in the electronic clock includes time difference information based on standard time, daylight saving time information applied to a predetermined date period, and the like.

The time adjustment mode as described above is selected based on whether the home country time is displayed or the local time is displayed, for example, when traveling overseas or traveling overseas. The time adjustment mode switching operation is performed. Is not complicated, and it is preferable that it can be performed by a simple operation.

The present invention has been made in view of such circumstances, and provides an electronic clock, a time adjustment method, and a program that can easily perform an operation of changing the time difference data to determine whether or not to perform time adjustment at the time of time adjustment. The purpose is to do.

In order to achieve the above object, the present invention is grasped by the following configuration.
The electronic clock of the present invention is a self-device based on a time measuring means for measuring a time, an input means for receiving an input, a measuring means for measuring the time when the input means is receiving an input, and a measurement result of the measuring means. It is provided with a control means for determining whether or not to change the time difference data set in the above, and a time adjusting means for correcting the time measured by the time measuring means based on the time difference data.

INDUSTRIAL APPLICABILITY According to the present invention, it is possible to provide an electronic clock, a time adjustment method, and a program that can easily perform an operation of changing the time difference data to determine whether or not to perform time adjustment at the time of time adjustment.

It is a front view of the electronic clock which concerns on one Embodiment of this invention. It is a block diagram of the electronic clock which concerns on one Embodiment of this invention. It is a flow diagram which shows the key processing of the electronic timepiece which concerns on one Embodiment of this invention. It is a flow diagram which shows the time adjustment process 1 (the first time adjustment mode) of the electronic timepiece which concerns on one Embodiment of this invention. It is a flow diagram which shows the time adjustment process 2 (second time adjustment mode) of the electronic timepiece which concerns on one Embodiment of this invention. It is a flow diagram which shows the BLE time adjustment process 1 of the electronic timepiece which concerns on one Embodiment of this invention. It is a flow diagram which shows the BLE time adjustment process 2 of the electronic timepiece which concerns on one Embodiment of this invention. It is a flow diagram which shows the GPS time adjustment process 1 of the electronic timepiece which concerns on one Embodiment of this invention. It is a flow chart which shows the GPS time adjustment process 2 of the electronic timepiece which concerns on one Embodiment of this invention. It is a flow figure which shows the automatic time adjustment processing of the electronic time | mouth which concerns on one Embodiment of this invention.

Hereinafter, the electronic clock 1 according to the embodiment of the present invention will be described with reference to the accompanying drawings.
In the following embodiment, the electronic clock 1 will be specifically described as a clock itself, but the electronic clock 1 of the present invention may be a clock or the like provided in an electronic device or the like, and may be the clock itself. Not limited.
FIG. 1 is a front view of the electronic clock 1 according to the embodiment of the present invention, and FIG. 2 is a block diagram of the electronic clock 1 according to the embodiment of the present invention.

As shown in FIGS. 1 and 2, the electronic clock 1 according to the present embodiment is a watch, and receives a timekeeping circuit 20 that functions as a timekeeping means for measuring time and GPS radio waves transmitted from GPS satellites 2. A GPS receiving unit 30, a short-range wireless communication unit 40 that communicates with a mobile terminal such as a smartphone 3, a date / time display unit 50 that displays the date and time, a sound output unit 60 that outputs sound, and a user's input operation. It is provided with a plurality of key switches S1 to S4 that function as input means for receiving the above, a control unit 70 that controls the entire electronic clock 1, and a bus 80 that connects them.

The timekeeping circuit 20, for example, measures the time in units of 1/256 seconds and outputs the seconds, minutes, hours, and days that are the measurement results.

The GPS receiving unit 30 includes a GPS module 31 that receives GPS radio waves from a plurality of GPS satellites 2, and a UART 32 that converts a serial signal and a parallel signal between the GPS module 31 and the bus 80.

The GPS radio wave includes time data indicating standard time (for example, UTC in Coordinated Universal Time) and position data indicating the position of each GPS satellite 2.

The GPS module 31 can measure the distance between the GPS satellite 2 and the electronic clock 1 based on the arrival time of the GPS radio wave, and by receiving the GPS radio wave from three or more GPS satellites 2, the earth of the electronic clock 1 The position (latitude and longitude) on the top can be specified.

The short-range wireless communication unit 40 is a Bluetooth (registered trademark) that is a short-range wireless communication standard. For example, a Bluetooth module 41 that communicates with a smartphone 3 and a serial signal and a parallel signal between the Bluetooth module 41 and the bus 80. The UART 42 that performs the conversion of the above is provided.

The Bluetooth module 41 of the present embodiment is compatible with BLE (Bluetooth Low Energy) capable of communicating with less power than the conventional Bluetooth (classic), and the communication with the smartphone 3 is appropriately referred to as BLE.

The smartphone 3 has a timekeeping circuit equivalent to that of the electronic clock 1, and also has time difference information based on standard time (UTC) (hereinafter, appropriately referred to as time difference) and daylight saving time information applied to a predetermined date period (hereinafter, appropriate). Time difference data including DST) is set.

In addition, the smartphone 3 has a function of acquiring time signal data from a time signal server via the Internet and receiving GPS radio waves from GPS satellites 2, and normally, time adjustment data acquired via the Internet and GPS. The time measured by the time signal circuit 20 is automatically corrected based on the GPS radio wave received from the satellite 2.

The date / time display unit 50 includes a second hand 51 for displaying seconds, a minute hand 52 for displaying minutes, an hour hand 53 for displaying hours, a day wheel 54 for displaying days, a second hand 51, a minute hand 52, an hour hand 53, and a day. It includes a train wheel 55 connected to the car 54, a motor 56 that operates the second hand 51, the minute hand 52, the hour hand 53, and the day wheel 54 via the wheel train 55, and a driver 57 that drives the motor 56.

The date / time display unit 50 of the present embodiment not only displays the date / time measured by the timekeeping circuit 20, but also functions as a processing result display unit that displays whether or not the processing performed by the control unit 70 is successful.

For example, a character "Y" indicating success in processing and a character "N" indicating failure in processing are provided at positions that can be pointed to by the second hand 51, and either character is controlled by the operation control of the second hand 51. By pointing, the processing result of the control unit 70 can be displayed.

The sound output unit 60 includes a piezo 61 that is a sound generation device, and a driver 62 that drives the piezo 61.
The sound output unit 60 is operated, for example, when outputting an alarm sound.

The key switches S1 to S4 are operated when using various functions of the electronic clock 1 and making various settings.
For example, in the present embodiment, the key switch S1 is used as an operation tool for performing reception result display, time adjustment processing 1, time adjustment processing 2, automatic time adjustment mode switching, and the like, which will be described later.

The control unit 70 functions as a control means, and includes a CPU 71, a read-only non-volatile memory ROM 72, a readable / writable volatile memory RAM 73, a readable / writable non-volatile memory such as a flash memory, and the like. A storage unit 74 is provided.

The ROM 72 stores not only a control program for performing general control of the electronic clock 1, but also table data and the like relating position information and time difference data (time difference information and summer time information), and the RAM 73 is controlled by the CPU 71. Data and the like generated in the process of performing control according to the program are stored, and various setting data and the like are stored in the storage unit 74.

For example, time difference data including time difference information (time zone) based on standard time (UTC) and daylight saving time information (DST) applied to a predetermined date period is stored in the storage unit 74.

The control unit 70 functions as a measuring means by cooperating with the timekeeping circuit 20 by operating the CPU 71 according to the control program stored in the ROM 72.
Further, the control unit 70 functions as a time adjustment means by operating the CPU 71 according to the control program stored in the ROM 72.
Although the details will be described later, the measuring means measures the operation time of the key switch S1, and the time adjusting means corrects the time measured by the time measuring circuit 20 according to the measurement result of the measuring means.

According to such a measuring means, a controlling means, and a time adjusting means, the time measured by the time measuring circuit 20 can be corrected only by operating the key switch S1 for a predetermined time, so that the time required to operate a plurality of key switches is compared with the case where a plurality of key switch operations are required. , The operation when adjusting the time can be simplified.

The time adjusting means of the present embodiment includes a time adjusting process 1 and a time adjusting process 2 for correcting the time measured by the time measuring circuit 20 by using different processing procedures, and sets the measurement result of the measuring means to a plurality of thresholds (for example, for example). 1.5 seconds and 3.0 seconds) are compared, and one of the time adjustment processes 1 and 2 is selected based on the comparison result.
According to such a time adjusting means, one of the time adjusting processes 1 and 2 can be selected based on the operation time of the key switch S1 to correct the time measured by the time measuring circuit 20.

In the case of the time adjustment process 1, the time adjustment means of the present embodiment does not change the time difference data (time difference information and summer time information) stored in the storage unit 74 of the electronic clock 1, and is external (GPS satellite 2 or smartphone). Based on the time adjustment data acquired from 3), the time measured by the time measuring circuit 20 is corrected.

On the other hand, in the case of the time adjustment process 2, the time difference data stored in the storage unit 74 of the electronic timepiece 1 is changed and the time measured by the time measuring circuit 20 is corrected based on the time adjustment data acquired from the outside. ..

According to such a time adjustment means, the time adjustment process 1 and the time adjustment process 2 are selectively executed based on whether the home country time is displayed or the local time is displayed when traveling overseas or traveling abroad. can do.

The time adjustment data includes GPS radio waves transmitted by the GPS satellite 2.
In the case of the time adjustment process 1, the time adjustment means is timed by the clock circuit 20 based on the time data included in the GPS radio wave received from the GPS satellite 2 without changing the time difference data set in the electronic clock 1. Correct the time to do.

On the other hand, in the case of the time adjustment process 2, the time difference data set in the electronic clock 1 is changed based on the position data included in the GPS radio waves received from the GPS satellites 2, and the GPS radio waves received from the GPS satellites 2 are used. The time measured by the clock circuit 20 is corrected based on the included time data.

According to such a time adjusting means, it is possible to adjust the time measured by the time measuring circuit 20 and change the time difference data set in the electronic clock 1 by using the GPS radio wave.

To change the time difference data based on GPS radio waves, GPS radio waves are received from three or more GPS satellites 2, and the distance between the three or more GPS satellites 2 and the electronic clock 1 is determined based on the arrival time of each GPS radio wave. A step of measuring, a step of specifying the position (latitude and longitude) of the electronic clock 1 on the earth based on the measured distance, and a step of extracting time difference data corresponding to the specified position by referring to the above-mentioned table data. And, it is executed through.

Further, the time adjustment data includes time data and time difference data held by the smartphone 3.

In the case of the time adjustment process 1, the time adjustment means sets the time measured by the clock circuit 20 based on the time data and the time difference data acquired from the smartphone 3 without changing the time difference data set in the electronic clock 1. Correct.

On the other hand, in the case of the time adjustment process 2, the time difference data set in the electronic clock 1 is changed based on the time difference data acquired from the smartphone 3, and the timekeeping circuit 20 is based on the time data acquired from the smartphone 3. Correct the time to be clocked.

According to such a time adjusting means, the time data and the time difference data possessed by the smartphone 3 are used to correct the time measured by the time measuring circuit 20 and to change the time difference data set in the electronic clock 1. be able to.

The time adjusting means of the present embodiment uses GPS radio waves, time data and time difference data possessed by the smartphone 3 to correct the time measured by the time measuring circuit 20 and to adjust the time difference data set in the electronic clock 1. In making the change, first, the time data and the time difference data are tried to be acquired from the smartphone 3, and when the acquisition fails, the GPS radio wave is received from the GPS satellite 2.

According to such a time adjusting means, the power saving BLE is prioritized over the reception of the GPS radio wave, so that the power consumption of the electronic clock 1 can be suppressed.

Next, a specific processing procedure of the control unit 70 that realizes the time adjustment means as described above will be described with reference to FIGS. 3 to 10.
FIG. 3 is a flow chart showing key processing of the electronic clock 1 according to the embodiment of the present invention.

FIG. 4 is a flow chart showing the time adjustment process 1 (first time adjustment mode) of the electronic clock 1 according to the embodiment of the present invention, and FIG. 5 is a time adjustment of the electronic clock 1 according to the embodiment of the present invention. It is a flow chart which shows process 2 (second time adjustment mode).

FIG. 6 is a flow chart showing the BLE time adjustment process 1 of the electronic clock 1 according to the embodiment of the present invention, and FIG. 7 is a flow showing the BLE time adjustment process 2 of the electronic clock 1 according to the embodiment of the present invention. It is a figure.

FIG. 8 is a flow chart showing the GPS time adjustment process 1 of the electronic clock 1 according to the embodiment of the present invention, and FIG. 9 is a flow showing the GPS time adjustment process 2 of the electronic clock 1 according to the embodiment of the present invention. It is a figure.

FIG. 10 is a flow chart showing an automatic time adjustment process of the electronic clock 1 according to the embodiment of the present invention.

As shown in FIG. 3, the control unit 70 executes key processing including reception result display, time adjustment processing 1, time adjustment processing 2, and mode switching of automatic time adjustment.
When the key processing starts, the control unit 70 first determines ON / OFF of the key switch S1 (step S11), and if the determination result is OFF, executes another key processing (step S12), and steps. Return to S11.

On the other hand, when the determination result in step S11 is ON, the control unit 70 determines ON / OFF of the key switch S1 again (step S13), and whether or not 1.5 seconds have passed from the ON of the key switch S1. Is determined (step S14).

Here, if the key switch S1 is turned off before 1.5 seconds have elapsed from the key switch S1 being turned on, the control unit 70 executes reception result display (step S15) and returns to step S11.

The reception result display is a process for displaying whether or not the latest time adjustment process has succeeded. For example, the character "Y" is displayed by pointing to the character "Y" with the second hand 51, and the character "N" is displayed with the second hand 51. "Failure" is displayed by pointing to.

On the other hand, when 1.5 seconds have elapsed from the ON of the key switch S1, the control unit 70 again determines ON / OFF of the key switch S1 (step S16), and 3.0 seconds have elapsed from the ON of the key switch S1. Whether or not it is determined (step S17).

Here, if the key switch S1 is turned off before 3.0 seconds have elapsed from the key switch S1 being turned on, the control unit 70 executes the time adjustment process 1 described later (step S18), and returns to step S11. ..

On the other hand, when 3.0 seconds have elapsed from the ON of the key switch S1, the control unit 70 again determines ON / OFF of the key switch S1 (step S19), and 4.5 seconds have elapsed from the ON of the key switch S1. Whether or not it is determined (step S20).

Here, if the key switch S1 is turned off before 4.5 seconds have elapsed from the key switch S1 being turned on, the control unit 70 executes the time adjustment process 2 described later (step S21) and returns to step S11. ..

On the other hand, when 4.5 seconds have elapsed from the ON of the key switch S1, the control unit 70 determines whether or not the automatic time adjustment mode described later is automatic (time difference data automatic change mode) (step S22). If the judgment result is YES, the automatic time adjustment mode is switched from automatic to fixed (time difference data fixed mode) (step S23), and if the judgment result is NO, the automatic time adjustment mode is switched from fixed to automatic. (Step S24).

After that, the control unit 70 determines ON / OFF of the key switch S1 again (step S25), and returns to step S11 when the key switch S1 is turned OFF.

Next, each process in the flow of FIG. 3 will be described in order.
When the process proceeds to step S18 of FIG. 3, the time adjustment process 1 shown in FIG. 4 starts.
In this case, the control unit 70 first determines whether or not the pairing between the electronic watch 1 and the smartphone 3 by BLE is completed (step S31), and if the determination result is YES, the BLE time described later. The correction process 1 is preferentially executed (step S32), but if the determination result is NO, the GPS time correction process 1 described later is executed (step S33).

Further, the control unit 70 determines the reception result (time adjustment result) after executing the BLE time adjustment process 1 (step S34), and if the determination result is successful, the control unit 70 ends the time adjustment process 1. If the determination result is unsuccessful, the GPS time adjustment process 1 is executed (step S33).

On the other hand, when the process proceeds to step S21 of FIG. 3, the time adjustment process 2 shown in FIG. 5 starts.
In this case, the control unit 70 first determines whether or not the pairing between the electronic watch 1 and the smartphone 3 by BLE is completed (step S41), and if the determination result is YES, the BLE time described later. The correction process 2 is preferentially executed (step S42), but if the determination result is NO, the GPS time correction process 2 described later is executed (step S43).

Further, the control unit 70 determines the reception result (time adjustment result) after executing the BLE time adjustment process 2 (step S44), and if the determination result is successful, the time adjustment process 1 is terminated. If the determination result is unsuccessful, the GPS time adjustment process 2 is executed (step S43).

Next, each process in FIGS. 4 and 5 will be described in order.
The difference between FIGS. 4 and 5 is that step S32 in FIG. 4 executes the BLE time adjustment process 1, whereas step S42 in FIG. 5 executes the BLE time adjustment process 2. And, while step S33 in FIG. 4 executes the GPS time adjustment process 1, step S43 in FIG. 5 executes the GPS time adjustment process 2, so that the difference in contents can be easily understood. The BLE time adjustment process 1, the BLE time adjustment process 2, the GPS time adjustment process 1, and the GPS time adjustment process 2 will be described in this order.

When the process proceeds to step S32 of FIG. 4, the BLE time adjustment process 1 shown in FIG. 6 starts.
In this case, the control unit 70 first executes the connection procedure with the smartphone 3 (step S51), requests the smartphone 3 to transmit the time difference and the DST, and receives the time difference and the DST transmitted from the smartphone 3. (Step S52).

Subsequently, the control unit 70 requests the smartphone 3 to transmit the date and time and 1/256 seconds, and receives the date and time and 1/256 seconds transmitted from the smartphone 3 (step S53).
If the smartphone 3 does not support 1/256 seconds, for example, the control unit 70 obtains 1/256 seconds from the seconds based on the time (for example, seconds) transmitted by the smartphone 3. Do (the same applies to the following).

Next, the control unit 70 determines whether or not the data necessary for the time adjustment process has been successfully received from the smartphone 3 (step S54), and if the determination result is YES, the control unit 70 has received 1 from the smartphone 3. Based on / 256 seconds, the time difference of 1/256 seconds of the time measured by the timekeeping circuit 20 is corrected, and the date time, time difference and DST received from the smartphone 3 and the time difference and DST set in the electronic clock 1 are used. Then, the date and time (seconds, minutes, hours, days) measured by the timekeeping circuit 20 are corrected (step S55).

That is, in the BLE time adjustment process 1, the time measured by the time measuring circuit 20 is corrected based on the date time, the time difference, and the DST received from the smartphone 3 without changing the time difference and the DST set in the electronic clock 1. Therefore, the standard time (UTC) is obtained by subtracting the time difference and DST received from the smartphone 3 from the date and time received from the smartphone 3, and is obtained by adding the time difference and DST set in the electronic clock 1 to this. The time measured by the time measuring circuit 20 is corrected based on the date and time.

Then, after executing the time adjustment process in step S55, the disconnection procedure with the smartphone 3 is executed (step S56), and the BLE time adjustment process 1 is terminated.

If the determination result in step S54 is NO, the disconnection procedure with the smartphone 3 is executed (step S56) without performing the time adjustment process in step S55, and the BLE time adjustment process 1 is terminated.
The determination result of step S54 is recorded and is also used for the determination of step S34 in FIG.
Further, if the determination result in step S54 is YES, recording for displaying "Y" in FIG. 1 is also performed when the process proceeds to step S15 in FIG.

On the other hand, when the process proceeds to step S42 of FIG. 5, the BLE time adjustment process 2 shown in FIG. 7 starts.
In this case, the control unit 70 first executes the connection procedure with the smartphone 3 (step S61), requests the smartphone 3 to transmit the time difference and the DST, and receives the time difference and the DST transmitted from the smartphone 3. (Step S62).

Subsequently, the control unit 70 requests the smartphone 3 to transmit the date and time and 1/256 seconds, and receives the date and time and 1/256 seconds transmitted from the smartphone 3 (step S63).

Next, the control unit 70 determines whether or not the data required for the time adjustment process has been successfully received from the smartphone 3 (step S64), and if the determination result is YES, the control unit 70 has received 1 from the smartphone 3. Corrects 1/256 seconds of the time measured by the timekeeping circuit 20 based on / 256 seconds, and the date and time (seconds, minutes, hours, Daylight saving time) is corrected, and the time difference and DST set in the electronic clock 1 are changed based on the time difference and DST received from the smartphone 3 (step S65).

Then, after executing the time adjustment process in step S65, the disconnection procedure with the smartphone 3 is executed (step S66), and the BLE time adjustment process 2 is terminated.

If the determination result in step S64 is NO, the disconnection procedure with the smartphone 3 is executed (step S66) without performing the time adjustment process in step S65, and the BLE time adjustment process 2 is terminated.
The determination result of step S64 is recorded and is also used for the determination of step S44 in FIG.
Further, if the determination result in step S64 is YES, recording for displaying "Y" in FIG. 1 is also performed when the process proceeds to step S15 in FIG.

When the process proceeds to step S33 of FIG. 4, the GPS time adjustment process 1 shown in FIG. 8 starts.
In this case, the control unit 70 first determines the number of supplements (the number of GPS satellites that can receive GPS radio waves) of the GPS satellites 2 (step S71), and if the number of supplements is 0, the GPS time adjustment process. End 1
In this case, when the process proceeds to step S15 in FIG. 3, recording for displaying “N” in FIG. 1 is performed.

On the other hand, when the number of supplements of the GPS satellites 2 is one or more, the control unit 70 acquires the time adjustment data from the GPS radio waves and generates the date time and 1/256 seconds based on the acquired data. (Step S72), 1/256 seconds of the time measured by the time measuring circuit 20 and the date time (seconds, minutes, hours, days) are corrected (step S73), and the GPS time correction process 1 is terminated.

In the case of the GPS satellite 2, the time adjustment data does not correspond to 1/256 seconds, so as mentioned earlier in the case of the smartphone 3, the control unit 70 is 1/256 based on the acquired data. The process of obtaining the seconds is performed to generate 1/256 seconds.

Further, when the process of step S73 is executed, recording for displaying "Y" in FIG. 1 is also performed when the process proceeds to step S15 of FIG.

When the process proceeds to step S43 of FIG. 5, the GPS time adjustment process 2 shown in FIG. 9 starts.
In this case, the control unit 70 first determines the number of supplements (the number of GPS satellites that can receive GPS radio waves) of the GPS satellites 2 (step S81), and the number of supplements is 0 to 2 (that is, 2 or less). ), The GPS time adjustment process 2 is terminated.
This is because the position of the electronic clock 1 on the earth cannot be correctly obtained, and therefore the time adjustment including the time difference and DST cannot be performed.
In this case, when the process proceeds to step S15 in FIG. 3, recording for displaying “N” in FIG. 1 is performed.

On the other hand, when the number of supplements of the GPS satellite 2 is 3 or more, the date and time, 1/256 seconds, the time difference and the DST are specified based on the time data and the position data included in the GPS radio wave (step S82). Based on the specified 1/256 second and date time, the time difference 20 is corrected for 1/256 second and date time, and the time difference set in the electronic clock 1 is set based on the specified time difference and DST. And DST are changed (step S83).
Then, when step S83 is executed, recording for displaying "Y" in FIG. 1 is performed when the process proceeds to step S15 in FIG.

As described above, the time difference and DST identification based on the position data included in the GPS radio waves are determined by each GPS satellite 2 and the electronic clock 1 based on the arrival time of the GPS radio waves received from three or more GPS satellites 2. This is performed by measuring the distance to and from, specifying the position of the electronic clock 1 on the earth based on the measured distance, and then extracting the time difference and DST corresponding to the specified position by referring to the table data.

The process described with reference to FIGS. 3 to 9 is a case where the user operates the key switch S1 to start the time adjustment, but the electronic clock 1 has a function of automatically adjusting the time to a predetermined time. Hereinafter, the automatic time adjustment process will be described with reference to FIG. 10.

As shown in FIG. 10, in the automatic time adjustment process, the control unit 70 constantly determines whether or not there is a minute carry (shift from 59 seconds to 00 seconds) (step S101).

Then, when it is determined that there is a minute carry, the control unit 70 determines whether the automatic time adjustment mode is automatic (time difference data automatic change mode) or fixed (time difference data fixed mode) (step S102). ..

Here, when it is determined that the automatic time adjustment mode is automatic, the control unit 70 determines that the current time is the set time for automatic time adjustment (for example, 5:02, 11:02, 17:02, 23:02). ) (Step S103), and if the determination result is NO, the process ends.

On the other hand, when it is determined that the current time is the set time for automatic time adjustment, the control unit 70 executes the BLE time adjustment process 2 shown in FIG. 7 described above (step S104), and then receives the reception result (step S104). The time adjustment result) is determined (step S105), and if the determination result is successful, the process ends.

If the reception result is unsuccessful, the control unit 70 executes the GPS time adjustment process 2 shown in FIG. 9 described above (step S108), but cannot receive the GPS radio wave when the electronic clock 1 is indoors. Since there is a high possibility, the set time (for example, 5:02,) in which the current time automatically adjusts the time is excluded, excluding the set time (for example, 23:02) in which the electronic clock 1 is likely to be indoors. 11:02, 17:02) is determined (step S106), and light / dark determination (detection of the generated voltage of the solar cell for power supply, etc.) is performed (step S107), and the determination result in step S106 is obtained. The GPS time adjustment process 2 is executed only when YES and the determination result in step S107 is bright, and in other cases, the process ends.
As a result, unnecessary execution of the GPS time adjustment process 2 is avoided, and power consumption is suppressed.

On the other hand, when it is determined in step S102 that the automatic time adjustment mode is fixed, the control unit 70 determines that the current time is the set time for automatic time adjustment (for example, 5:02, 11:02, 17:02, 23). : 02) It is determined whether or not it is (step S109), and if the determination result is NO, the process is terminated.

When it is determined that the current time is the set time for automatic time adjustment, the control unit 70 determines today's reception result (time adjustment result) (step S110), and if the determination result is successful, processes it. To finish.

In other words, in the automatic mode that involves changing the time difference data, the time to move to the place where the time difference occurs is unknown, so the time adjustment process is executed multiple times a day, but in the fixed mode that does not involve changing the time difference data. Since the time adjustment process once a day is sufficient, the time adjustment process multiple times in a day is avoided and the power consumption is suppressed.

On the other hand, when the determination result in step S110 fails, the control unit 70 determines the reception result after executing the BLE time adjustment process 1 shown in FIG. 6 described above (step S111), and then determines the reception result (step S112). If the judgment result is successful, the process ends.

If the reception result is unsuccessful, the control unit 70 executes the GPS time adjustment process 1 shown in FIG. 8 described above (step S115), but again, as before, when the electronic clock 1 is in the room. Excludes the set time (for example, 23:02) where the electronic clock 1 is likely to be indoors because there is a high possibility that GPS radio waves cannot be received, and the current time is set to automatically adjust the time again. (For example, 5:02, 11:02, 17:02) is determined (step S113), and light / dark determination (detection of the generated voltage of the solar cell for power supply, etc.) is performed (step S114). The GPS time adjustment process 1 is executed only when the determination result in S113 is YES and the determination result in step S114 is bright, and in other cases, the process ends.
As a result, as in the previous case, unnecessary execution of the GPS time adjustment process 1 is avoided, and power consumption is suppressed.

Although the electronic clock 1 of the present invention has been described above based on the specific embodiment, the present invention is not limited to the above specific embodiment, and the technical scope of the present invention includes. Various modifications and improvements are included to the extent that the object of the present invention is achieved, which is clear to those skilled in the art from the description of the scope of claims.

The inventions described in the claims originally attached to the application of this application are described below. The claims described in the appendix are the scope of the claims originally attached to the application for this application.
<Claim 1>
Timekeeping means to measure the time and
Input means that accepts input and
A measuring means for measuring the time when the input means is accepting input, and a measuring means.
A control means for determining whether or not to change the time difference data set in the own device based on the measurement result of the measurement means, and
An electronic timepiece comprising: a time adjusting means for correcting a time measured by the timing means based on the time difference data.
<Claim 2>
The time adjusting means includes a plurality of time adjusting modes for correcting the time measured by the time measuring means by using different processing procedures.
The electron according to claim 1, wherein the measurement result of the measuring means is compared with a plurality of threshold values, and the time adjustment mode to be applied is selected from the plurality of time adjustment modes based on the comparison result. clock.
<Claim 3>
The plurality of time adjustment modes include at least a first time adjustment mode and a second time adjustment mode.
The time adjusting means is
In the first time adjustment mode, the time measured by the time measuring means is corrected based on the time adjustment data acquired from the outside without changing the time difference data set in the electronic timepiece.
In the second time adjustment mode, the time difference data set in the electronic timepiece is changed based on the time adjustment data acquired from the outside, and the time measured by the time measuring means is corrected. The electronic clock according to claim 2.
<Claim 4>
The time difference data set in the electronic clock includes
Time difference information based on standard time and
The electronic clock according to claim 3, wherein the electronic clock includes daylight saving time information applied to a predetermined date period.
<Claim 5>
The time adjustment data is a GPS signal transmitted by a GPS satellite.
The time adjusting means is
In the first time adjustment mode, the time measured by the time measuring means based on the time data included in the GPS signal received from the GPS satellite without changing the time difference data set in the electronic clock. And fix it
In the second time adjustment mode, the time difference data set in the electronic clock is changed based on the position data included in the GPS signal received from the GPS satellite, and the GPS signal received from the GPS satellite is changed. The electronic clock according to claim 3 or 4, wherein the time measured by the measuring means is corrected based on the time data included in the above.
<Claim 6>
The time adjustment data is time data and time difference data held by the mobile terminal.
The time adjusting means is
In the first time adjustment mode, the time measured by the time measuring means is corrected based on the time data and the time difference data acquired from the mobile terminal without changing the time difference data set in the electronic timepiece. death,
In the second time adjustment mode, the time difference data set in the electronic timepiece is changed based on the time difference data acquired from the mobile terminal, and the time difference data acquired from the mobile terminal is used as the basis for the time difference data. The electronic clock according to any one of claims 3 to 5, wherein the time measuring means corrects the time measured.
<Claim 7>
The electron according to claim 6, wherein the time adjusting means first attempts to acquire time data and time difference data from the mobile terminal, and receives a GPS signal from the GPS satellite when the acquisition fails. clock.
<Claim 8>
It is a time adjustment method in an electronic clock.
The timekeeping process to time the time and
The input process that accepts input and
A measurement process for measuring the time when the input means accepts input, and
A control process for determining whether or not to change the time difference data set in the own device based on the measurement result of the measuring means, and
A time adjustment method including a time adjustment step of adjusting the time measured by the time measuring means based on the time difference data.
<Claim 9>
A computer provided with a time measuring means for measuring time, an input means for receiving input, and a measuring means for measuring the time when the input means is receiving input.
A control means for determining whether or not to change the time difference data set in the own device based on the measurement result of the measuring means.
A program for functioning as a time adjusting means for correcting the time measured by the timing means based on the time difference data.

1 Electronic clock 2 GPS satellite 3 Smartphone 20 Timekeeping circuit 30 GPS receiver 31 GPS module 32 UART
40 Near field communication unit 41 Bluetooth module 42 UART
50 Date time display 51 Second hand 52 Minute hand 53 Hour hand 54 Day wheel 55 Wheel train 56 Motor 57 Driver 60 Sound output unit 61 Piezo 62 Driver 70 Control unit 71 CPU
72 ROM
73 RAM
74 Storage unit 80 Bus S1 to S4 key switch

In order to achieve the above object, the present invention is grasped by the following configuration.
The electronic clock of the present invention
Timekeeping means to measure the time and
Input means that accepts input and
Acquisition means for acquiring GPS signals from GPS satellites,
A control means having a first time adjustment mode for performing the first time adjustment process and a second time adjustment mode for performing the second time adjustment process, and
Equipped with
The first time adjustment process changes the time difference data set in the own device based on the position data included in the GPS signal acquired by the acquisition means, and the GPS acquired by the acquisition means. It is a process of correcting the time measured by the time measuring means based on the time data included in the signal.
In the second time adjustment process, the time measuring means measures the time based on the time data included in the GPS signal acquired by the acquiring means without changing the time difference data set in the own device. It is a process to correct the time,
The control means is
When the input means detects an input that has continued for a predetermined time or longer, if the current mode is the first time adjustment mode, the mode is switched to the second time adjustment mode, and the current mode is the second time adjustment mode. If there is, switch to the first time adjustment mode,
In the first time adjustment process and the second time adjustment process, when the time measured by the time measuring means reaches a predetermined time, the brightness detected by the predetermined sensor is equal to or higher than the predetermined threshold value. It starts at .

Claims (9)

Timekeeping means to measure the time and
Input means that accepts input and
A measuring means for measuring the time when the input means is accepting input, and a measuring means.
A control means for determining whether or not to change the time difference data set in the own device based on the measurement result of the measurement means, and
An electronic timepiece comprising: a time adjusting means for correcting a time measured by the time measuring means based on the time difference data. The time adjusting means includes a plurality of time adjusting modes for correcting the time measured by the time measuring means by using different processing procedures.
The electron according to claim 1, wherein the measurement result of the measuring means is compared with a plurality of threshold values, and the time adjustment mode to be applied is selected from the plurality of time adjustment modes based on the comparison result. clock. The plurality of time adjustment modes include at least a first time adjustment mode and a second time adjustment mode.
The time adjusting means is
In the first time adjustment mode, the time measured by the time measuring means is corrected based on the time adjustment data acquired from the outside without changing the time difference data set in the electronic timepiece.
In the second time adjustment mode, the time difference data set in the electronic timepiece is changed based on the time adjustment data acquired from the outside, and the time measured by the time measuring means is corrected. The electronic clock according to claim 2. The time difference data set in the electronic clock includes
Time difference information based on standard time and
The electronic clock according to claim 3, wherein the electronic clock includes daylight saving time information applied to a predetermined date period. The time adjustment data is a GPS signal transmitted by a GPS satellite.
The time adjusting means is
In the first time adjustment mode, the time measured by the time measuring means based on the time data included in the GPS signal received from the GPS satellite without changing the time difference data set in the electronic clock. And fix it
In the second time adjustment mode, the time difference data set in the electronic clock is changed based on the position data included in the GPS signal received from the GPS satellite, and the GPS signal received from the GPS satellite is changed. The electronic clock according to claim 3 or 4, wherein the time measured by the measuring means is corrected based on the time data included in the above. The time adjustment data is time data and time difference data held by the mobile terminal.
The time adjusting means is
In the first time adjustment mode, the time measured by the time measuring means is corrected based on the time data and the time difference data acquired from the mobile terminal without changing the time difference data set in the electronic timepiece. death,
In the second time adjustment mode, the time difference data set in the electronic timepiece is changed based on the time difference data acquired from the mobile terminal, and the time difference data acquired from the mobile terminal is used as the basis for the time difference data. The electronic clock according to any one of claims 3 to 5, wherein the time measuring means corrects the time measured. The electron according to claim 6, wherein the time adjusting means first attempts to acquire time data and time difference data from the mobile terminal, and receives a GPS signal from the GPS satellite when the acquisition fails. clock. It is a time adjustment method in an electronic clock.
The timekeeping process to time the time and
The input process that accepts input and
A measurement process for measuring the time when the input means accepts input, and
A control process for determining whether or not to change the time difference data set in the own device based on the measurement result of the measuring means, and
A time adjustment method including a time adjustment step of adjusting the time measured by the time measuring means based on the time difference data. A computer provided with a time measuring means for measuring time, an input means for receiving input, and a measuring means for measuring the time when the input means is receiving input.
A control means for determining whether or not to change the time difference data set in the own device based on the measurement result of the measuring means.
A program for functioning as a time adjusting means for correcting the time measured by the timing means based on the time difference data.

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